DE3729741C2 - Multipole circuit breaker - Google Patents

Description

The invention relates to a multi-pole circuit breaker, with a housing with two side walls and at least two Partitions that have a middle compartment and between each other form at least two side compartments; a medium one Switch located in the middle compartment and on stationary contact piece, a movable contact arm and Has connections for external connection; one each side switch that in the respective side compartment is arranged and in each case a stationary contact piece, a movable contact arm and connections for external connection having.

Figs. 1 to 3 show an embodiment of a conventional multi-pole circuit breaker.

Fig. 1 shows a front view of such a circuit breaker, the cover being partially omitted.

Fig. 2 shows a sectional view along the line II-II in Fig. 1, and

Fig. 3 shows a sectional view along the line III-III in Fig. 2nd

Referring to FIGS. 1 to 3, the multi-pole circuit breaker comprises an electrically insulating housing 1 composed of a base 1 B and a cover 1 A. The housing 1 includes two outer side walls 1 a and two partition walls 1 b, which form between them three compartments , in which a middle switch A and side switch B are arranged. On the base 1 B of the housing 1 , a stationary contact 2 is permanently mounted, which has a stationary contact piece 2 a at one end and at its other end with a connection 17 B including a connection screw hole 2 b. An arc guide 3 and an electrically insulating housing 4 are mounted on the stationary contact 2 , and a frame 5 is also attached to the base 1 b, with screws 6 , only one of which is shown. The frame 5 carries on its projection 5 a an operating handle 7 , so that the operating handle 7 is rotatable about the projection 5 a. On the actuating handle 7 , a fork or cradle 8 is mounted, which is rotatable relative to the actuating handle 7 .

A toggle joint 10 , which has an upper toggle lever 10 a and a lower toggle lever 10 b, which is rotatably connected to the upper toggle lever 10 a with a knee lever pin 11 , is connected to the actuating handle 7 via an upper toggle lever pin 9 at the upper end of the upper Knee lever 10 a connected. The lower end of the lower knee lever 10 b is connected via a pin 14 to a cross bar 13 which is rotatably mounted with respect to the base 1 B.

The toggle pin 11 of the toggle joint 10 is biased in the direction of the actuating handle 7 with a tension spring 12 which is arranged between the toggle lever pin 11 and the actuating handle 7 and is connected thereto, so that the upper toggle lever 10 a is held in engagement with the toggle pin 9 . A movable contact arm 15 with an attached movable contact piece 15 a is rotatably mounted on the crossbar 13 with an axis 16 . The movable contact arm 15 is electrically connected via a flexible conductor 18 to a connecting conductor 17 which is fastened to the base 1 B and has a connection 17 A with a screw hole 17 a.

The circuit breaker also has an electromagnetic tripping device, which comprises an electromagnetic device 19 with a movable piston 19 a. Furthermore, a thermally responsive triggering device is provided with a bimetal 20 with an adjusting screw 20 a. In order to accommodate the movements of both types of release devices, a switch or release rod 21 is provided, which can be rotated by the screw 20 a or the piston 19 a. The trigger rod 21 is in engagement with a bolt or a pawl 22 , which in turn is in engagement with a bolt or a pawl 23 which releasably locks the fork 8 . An arc extinguisher 24 , which has a plurality of arc quenching plates 24 a, is also housed in the housing.

In a manner known per se, the actuating handle 7 in the arrangement described above is only provided for the middle switch, which is placed in the middle compartment. However, since all movable contact arms 15 of switches A and B are connected to one another via crossbar 13 , they move together when the middle switch A is moved manually or when at least one of the three switches A and B is triggered.

When the power switch is in the ON position of FIG. 1 to 3, the current from the stationary contact 2 flows to the connection conductor 17 through the stationary contact piece 2 a, the movable contact piece 15 a, the movable contact arm 15 and the flexible conductor 18 . When the operating handle 7 is moved in the direction of an arrow 25 , the upper end of the tension spring 12 is moved beyond the dead center of the line of action of the tension spring 12 so that the toggle joint 10 collapses due to the action of the tension spring 12 , the movable contact arm 15 being together is moved upward with the crossbar 13 until the movable contact arrangement assumes the OFF position.

If a very large current flows through the circuit breaker in the ON position according to FIG. 1, the electromagnetic release device is actuated and pushes the piston 19 a out of the electromagnetic device 19 . On the other hand, if an overcurrent flows through the circuit breaker in the ON position shown in FIG. 1, the thermally responsive tripping device is actuated and presses the adjusting screw 20 a against the tripping rod 21st

In both cases, the trigger rod 21 is rotated so that the pawl 22 and then the pawl 23 are rotated, with the result that the fork 8 is triggered under the action of the tension spring 12 which biases the fork 8 in such a way that it turns clockwise. The fork 8 is then rotated clockwise in Fig. 2, so that the toggle lever pin 9 moves over center and causes the toggle link 10 collapses, so that the movable contact arm 15 bar, together with the cross is rotated about the axis 16 13 until they are brought into the release position in which the movable contact piece 15 a is separated from the stationary contact piece 2 a.

In the multi-pole circuit breaker of the type described above, the stationary contacts 2 in the three switches A and B have the same configuration as shown in FIGS. 1 and 3. Thus, the distance y between the center lines x, which pass through the centers of the stationary contact pieces 2 a, the movable contact arms 15 and the arc extinguisher 24 of the respective switches A and B, is equal to the distance z between the center lines of the connections 17 A and 17 B or the center lines that pass through the connecting screw holes 2 b and 17 a.

Thus, as can be seen most clearly from FIG. 1, the outer side walls 1 a are substantially thinner in the area which is adjacent to the main mechanism, including the stationary contact pieces 2 a, the movable contact arms 15 and the arc extinguisher 24 , than the area which adjacent to the terminals 17 A and 17 B, and as the partitions 1 b, which are provided between the switches A and B. If it is desired to increase the strength of the outer side walls 1 a of the housing 1 , the thickness of the outer side walls must be increased, so that the width dimension of the housing 1 must also be larger.

A circuit breaker of the type mentioned is, for example known from DE 28 02 554 B1. It's about there the problem, a much higher security against the Transition of switching gases into neighboring pole tracks both the same as well as neighboring switches and against education of electric crawlers in the places mentioned the circuit breaker to offer.

For this purpose, the conventional circuit breaker according to DE 28 02 554 B1, with a along a parting line insulating housing divided into an upper part and a lower part as well as with overlapping partitions is provided between the pole tracks of the switch for Problem solving provided that the partitions of the upper part and the lower part of each other along their entire length and the Outer walls of both housing parts essentially on each other overlap their entire length. Leave this pamphlet however, no measures can be taken, such as the manufacture of such a circuit breaker easier and at the same time the mechanical strength is increased.

The invention has for its object in a circuit breaker the manufacturability of the type mentioned at the beginning to facilitate and increase its mechanical strength, without the entire width dimension of the housing is enlarged.

The solution according to the invention is a circuit breaker of the type mentioned in such a way that the Wall thicknesses of the walls of the housing are approximately the same and that the side switches inside, to the middle switch are offset so that the distance between the Center lines passing through the centers of the stationary contact pieces and the movable contact arms of the respective middle and go through the side switch is smaller than the distance between the center lines of the connections.  

According to the invention the object is more satisfactory Solved way, without the need to meet the whole Enlarge the width of the housing. So it fits such circuit breaker in the usual equidistant grid arrangement of external connections with which such circuit breakers be installed in circuit networks. Have along the side walls have increased mechanical strength, and the manufacture of the housing parts is facilitated because the same wall thickness is used to cool the mold Manufacture of such housings more uniform and thus improved.

The invention is described below based on the description of a  Embodiment and with reference to the accompanying Drawing explained in more detail. The drawing shows in

Fig. 1 is a front view of a conventional multi-pole circuit breaker, with the cover partially omitted;

Fig. 2 is a side view in section along the line II-II in Fig. 1;

Fig. 3 is a sectional view taken along the line III-III in Fig. 2;

Fig. 4 is a front view of the circuit breaker according to the invention, the lid being partially omitted; and in

Fig. 5 is an illustration for explaining the main part of the circuit breaker of FIG. 4.

In the following, on Fig. 4 and 5 referred to, which show an embodiment of the multi-pole circuit breaker according to the invention, of the same structure, in many respects, has as the multipolar power switch described above, however, the side switch has a special design with respect.

As shown in FIGS. 4 and 5, the multi-pole circuit breaker has an electrically insulating housing 26 which comprises a base 26 B and a cover 26 A. The housing 26 has two side walls 26 a and two partitions 26 b, which together form a central compartment 28 and two side compartments 29 . A middle switch A is housed in the middle compartment 28 and has a stationary contact piece 2 a, a movable contact arm 15 , an arc extinguisher, not shown, and connections 27 A and 27 B for external connection.

A side switch B is housed in each of the side compartments 29 and each has a stationary contact element 2 a, a movable contact arm 15 , an arc extinguisher, not shown, and connections 27 A and 27 B for external connection.

According to the invention, the distances y1 between center lines x which pass through the centers of the stationary contact elements 2 a, the movable contact arms 15 and the arc extinguisher (not shown in FIGS. 4 and 5) of the respective switches A and B are smaller than a distance z between the center lines x2 of the connections 27 A and 27 B. While the connections 27 A and 27 B are thus arranged at equal intervals between one another and the connections 27 A and 27 B for the respective switches A and B in the width direction are the same distance extend as in the conventional arrangement, the movable contact arm 15 and the arc extinguisher for the respective switches A and B extend in the width direction by a smaller distance than in the conventional arrangement by a value that is the difference between the center line distances y and y corresponds to 1. This difference creates additional space on the outside of the respective side switch B.

This additional space can be used as a space for an additional thickness or wall thickness of the outer side walls 26 a of the housing 26 , which results in an increase in the mechanical strength of the side walls 26 a, without increasing the overall width dimension of the housing 26 . Thus, the current breaking capacity of the circuit breaker can be increased by a value which corresponds to the greater strength of the side walls 26 a of the housing 26 . While the partitions 26 b between the compartments are thinner than those in the conventional arrangement according to FIGS. 1 to 3, they are still as thick as the side walls 26 a, so that they have sufficient mechanical strength. If the wall thicknesses of the side walls 26 a and the partition walls 26 b of the cover 26 A and the base 26 B of the housing 26 are the same, the formability of the cover 26 A and the base 26 B is improved.

Claims (2)

Multipole circuit breaker, with

• - a housing ( 26 ) with two side walls ( 26 a) and at least two partition walls ( 26 b), which form a central compartment ( 28 ) and at least two side compartments ( 29 ) between one another,
• - A middle switch (A), which is arranged in the middle compartment ( 28 ) and has a stationary contact piece ( 2 a), a movable contact arm ( 15 ) and connections ( 27 A) for external connection,
• - Each has a side switch (B) which is arranged in the respective side compartment ( 29 ) and each has a stationary contact piece ( 2 a), a movable contact arm ( 15 ) and connections ( 27 B) for external connection,

characterized in that the wall thicknesses of the walls of the housing ( 26 ; side walls 26 a, partitions 26 b, cover 26 A, base 26 B) are approximately the same and
that the side switches (B) are offset inwards towards the middle switch (A) in such a way
that the distance (y1) between the center lines (x1) passing through the centers of the stationary contact piece ( 2 a) and the movable contact arms ( 15 ) of the respective middle and side switches (A, B) is smaller than the distance ( z) between the center lines (x2) of the connections ( 27 A, 27 B).